Abstract
Multi-layer targets and nonideal initial conditions significantly increase the complexity of penetration trajectory prediction. To address this issue, a general multi-layer target trajectory model was developed based on expanding spherical cavity in layered finite targets, comprising the wake separation and finite free-surface effects. The trajectory prediction model adopted the developed geometric description of the ogive- and conical-nosed projectiles, combined with the proposed transfer functions and plane motion equation. Experiments of the two types projectiles penetration into layered 2A12 aluminum targets were conducted, and the actual projectile trajectories in targets were obtained through the section scan method. The predicted trajectories aligned well with the experimental data within the application range. The layering effect considerably influences the projectile trajectories impacting at higher velocities and oblique angles. More layers reduce the resistance of the targets, increasing the penetration but reducing the angle deflection of the trajectory performance. Compared with the ogive projectile, the conical projectile exhibited a deeper penetration and improved anti-deflection capabilities. This preliminary study on penetration trajectory characteristics of multi-layer targets provides experimental and theoretical support for correcting penetration trajectories.
Published Version
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